JP2022097703A - Electric power tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric power tool which can monitor the condition of a user who uses the electric power tool.

SOLUTION: An electric power tool 10 comprises: a drive part 11; an operation part 12; a controller 14; a grip part 21; and a force sensor 131. The drive part 11 drives a tool. The operation part 12 accepts an operation to activate the drive part 11. The controller 14 controls an operative condition of the drive part 11 based on an input signal from the operation part 12. The grip part 21 is arranged at a tool body 20 to be a grip which a user grasps. The force sensor 131 measures force applied to the grip part 21 to monitor vibration or load which the user suffers.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a power tool.

Conventionally, there has been an electric tool provided with a mode selection switch for selecting an operation mode from the outside (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2004-314298

An object of the present invention is to provide a power tool capable of monitoring the state of a user who uses the power tool.

In the power tool of one aspect of the present invention, the drive unit for driving the tool, the operation unit for receiving the operation for operating the drive unit, and the operating state of the drive unit are based on the input signal from the operation unit. A force sensor that measures the force applied to the grip unit to monitor the vibration or load force that the user suffers, the control unit that is controlled by the tool, the grip unit that is provided on the tool body and is the part that the user has. And prepare.

According to the present invention, the state of the user who uses the power tool can be monitored.

FIG. 1A is a block diagram of a power tool according to the first embodiment of the present invention. FIG. 1B is a block diagram of a repeater of a power tool management system including the same power tool. FIG. 1C is a block diagram of a management device of a power tool management system including the same power tool. FIG. 2 is a system configuration diagram of the same power tool management system. FIG. 3 is a system configuration diagram of the same power tool management system. FIG. 4 is a block diagram of the power tool according to the second embodiment of the present invention.

The embodiments described below are merely examples of the power tool according to the present invention and the power tool management system including the power tool. The present invention is not limited to the following embodiments, and the following embodiments can be variously modified according to the design and the like as long as the object of the present invention can be achieved.

(Embodiment 1)
(1) Overview As shown in FIG. 1A, the power tool 10 of the present embodiment includes a drive unit 11, an operation unit 12, a detection unit 13, and a control unit 14. The drive unit 11 drives a tool (for example, a socket 24) (see FIG. 2). The operation unit 12 receives an operation for operating the drive unit 11. The detection unit 13 detects whether the tool body 20 (see FIG. 2) is in a holding state held by the user or the tool body 20 is in a non-holding state not held by the user. The control unit 14 controls the operation state of the drive unit 11 to an operation state set based on the input signal from the operation unit 12 and the detection result by the detection unit 13.

Further, as shown in FIG. 3, the power tool management system 1 of the present embodiment includes a plurality of power tools 10 (101, 102, 103) (for example, three in the example of FIG. 3) and a management device 30. Be prepared. The management device 30 manages the work contents of the power tool 10.

The power tool management system 1 of the present embodiment includes three power tools 101, 102, 103, but the number of power tools is not limited to three, and the number of power tools may be one. It may be two or four or more. Further, in the following description, when the individual power tools are described, they are described as power tools 101, 102, 103, and when the description common to the power tools 101, 102, 103 is described, they are described as power tools 10.

(2) Details The power tool management system 1 of the present embodiment further includes a relay device 40 in addition to the power tool 10 and the management device 30.

Hereinafter, the configurations and operations of the power tool 10, the management device 30, and the relay device 40 will be described with reference to the drawings.

(2.1) Description of Power Tool 10 The power tool 10 of the present embodiment is a tool for a business operator used in, for example, a factory or a construction site. In the power tool 10 of the present embodiment, as shown in FIG. 2, a socket 24 for tightening a hexagon bolt is attached to an output shaft to which the rotation of the electric motor is transmitted. The power tool 10 is a power tool that rotates a socket 24 attached to an output shaft by rotating an output shaft with an electric motor and tightens a bolt having a head inserted into the socket 24. The electric tool 10 has a built-in hammer that hits the output shaft according to the rotation of the electric motor. By hitting the output shaft, tightening work with higher torque than the output of the electric motor can be performed. It can be carried out.

As shown in FIG. 1A, the power tool 10 of the present embodiment further includes a communication unit 15, a display unit 16, a measurement unit 17, a storage unit 18, and a power supply unit 19. Further, the power tool 10 of the present embodiment holds a drive unit 11, an operation unit 12, a detection unit 13, a control unit 14, a communication unit 15, a display unit 16, a measurement unit 17, a storage unit 18, and a power supply unit 19. It is equipped with a tool body 20 (see FIG. 2).

As shown in FIG. 2, the tool body 20 of the power tool 10 includes a grip portion 21, a cylindrical body portion 22, and a mounting portion 23. An output shaft (not shown) is exposed from one end side of the body portion 22 in the axial direction, and a tool suitable for the member to be worked is attached to this output shaft. In this embodiment, the socket 24 is attached to the output shaft of the power tool 10.

The grip portion 21 is a portion to be gripped when the user performs work using the power tool 10. One end side of the grip portion 21 in the longitudinal direction is connected to the peripheral surface of the body portion 22, and the other end side of the grip portion 21 in the longitudinal direction is connected to the mounting portion 23.

The battery pack 181 is attached to the attachment portion 23 in a removable state. The battery pack 181 has a built-in rechargeable battery. When the battery pack 181 removed from the mounting portion 23 is attached to a charger (not shown), the battery pack 181 is charged by the charger.

The drive unit 11 receives a control command from the control unit 14 to rotate the electric motor and rotate the output shaft to which the tool (socket 24) is attached.

The operation unit 12 includes a trigger switch 121 (see FIG. 2) attached to the grip unit 21. The user of the power tool 10 can operate the trigger switch 121 while holding the grip portion 21. The operation unit 12 outputs an input signal corresponding to the operation amount of the trigger switch 121 to the control unit 14.

The detection unit 13 includes a force sensor 131 (see FIG. 2) attached to the grip unit 21. The force sensor 131 measures the magnitude of the force applied to the grip portion 21. The force sensor 131 is made of, for example, a sheet-shaped piezoelectric element, and is provided as a whole on the surface of the grip portion 21. The force sensor 131 may be provided integrally with the resin rubber grip provided on the grip portion 21.

Based on the measurement result of the force sensor 131, the detection unit 13 is in a holding state in which the tool body 20 is held by the user, or is in a non-holding state in which the tool body 20 is not held by the user. Is detected. That is, the detection unit 13 detects that the force sensor 131 is in the holding state if the measurement result is equal to or more than the preset threshold value, and detects that the force sensor 131 is in the non-holding state if the measurement result is less than the threshold value. do. In the comparison between two values, "greater than or equal to" includes both the case where the two values are equal and the case where one of the two values exceeds the other. However, the present invention is not limited to this, and "greater than or equal to" here may be synonymous with "greater than" including only the case where one of the two values exceeds the other. That is, whether or not the two values are equal can be arbitrarily changed depending on the setting of the reference value and the like, so that there is no technical difference between "greater than or equal to" and "greater than or equal to". Similarly, "less than" may be synonymous with "less than or equal to".

Further, the detection unit 13 can also detect the amount of load applied to the user of the power tool 10 based on the measurement result of the force sensor 131. As the load applied to the user increases, the force with which the user grips the grip portion 21 increases. Therefore, the detection unit 13 detects the load applied to the user based on the measurement result of the force sensor 131. Can be done.

The control unit 14 includes an embedded computer having a CPU (Central Processing Unit) and a memory. By executing the program stored in the memory by the CPU, various functions of the power tool 10 are realized. Here, the program is recorded in advance in the memory of the computer, but may be provided through a telecommunication line such as the Internet, or may be recorded and provided in a recording medium such as a memory card.

The communication unit 15 performs wireless communication using radio waves as a medium via the antenna 151. The communication method of the communication unit 15 is preferably a communication method that does not require a license for a radio station. The communication unit 15 of the present embodiment is, for example, a communication module having a communication method compliant with the Wi-Fi (registered trademark) standard. The communication unit 15 is not limited to a communication module having a communication method conforming to the Wi-Fi (registered trademark) standard, and may be a communication module such as a low power radio (specified low power radio) that does not require a license. For this type of low-power radio, specifications such as frequency band and antenna power to be used are specified in each country according to the application. In Japan, low-power radios that use radio waves in the 920 MHz band or 420 MHz band are specified.

The display unit 16 includes, for example, an indicator lamp such as an LED (Light Emitting Diode). The display unit 16 displays the state of the power tool 10 by turning on, blinking, or turning off the display lamp.

The measuring unit 17 measures the work result information regarding the work result by the tool. The measuring unit 17 includes, for example, a torque measuring unit 171 that measures the tightening torque of the bolt as work result information, and an acceleration sensor 172 arranged inside the tool body 20.

In the present embodiment, since the power tool 10 is an impact wrench, the torque measuring unit 171 counts the number of times the striking force is applied to the tool (output shaft), and measures the tightening torque based on the number of striking times. The torque measuring unit 171 includes, for example, a microphone built in the tool body 20, counts the number of hitting sounds generated at the time of hitting, that is, the number of hits, based on the output of the microphone, and tightens based on the number of hits. All you have to do is measure the torque.

Further, the acceleration sensor 172 comprises, for example, a three-axis acceleration sensor, and measures the acceleration applied to the tool body 20.

The storage unit 18 is composed of a device selected from a ROM (Read Only Memory), a RAM (Random Access Memory), an EEPROM (Electrically Erasable Programmable Read Only Memory), and the like. The storage unit 18 stores identification information (address, etc.) individually assigned to the power tool 10, work result information measured by the measurement unit 17, and the like.

The power supply unit 19 uses the battery pack 181 as a power source to generate an electric motor and electric power to be supplied to an electric circuit such as the control unit 14.

(2.2) Explanation of Management Device 30 As shown in FIG. 1C, the management device 30 includes a signal processing unit 31, a communication unit 32, a display unit 33, an operation unit 34, and a storage unit 35.

The signal processing unit 31 includes a computer having a CPU and a memory. By executing the program stored in the storage unit 35 by the CPU, various functions of the management device 30 are realized. Here, although the program is recorded in advance in the storage unit 35, it may be provided through a telecommunication line such as the Internet, or may be recorded and provided on a recording medium such as a memory card.

The communication unit 32 performs wireless communication using radio waves as a medium via the antenna 321. The communication method of the communication unit 32 is preferably a communication method that does not require a license for a radio station, and may be the same communication method as the communication unit 15 of the power tool 10.

The display unit 33 is a display device such as a liquid crystal display.

The operation unit 34 includes an input device such as a keyboard, a mouse, and a pointing device.

The storage unit 35 is an external storage device such as a hard disk device. The storage unit 35 stores, for example, a set value of the tightening torque, the number of bolts for which the tightening work is performed, and the like as operating conditions of the drive unit 11 when the work is performed using the power tool 10. Further, the storage unit 35 stores work result information (for example, information on the measured value of the tightening torque and information on the number of times the tightening work is performed) acquired from the power tool 10.

(2.3) Description of Relay Device 40 As shown in FIG. 1B, the relay device 40 includes a communication control unit 41, a communication unit 42, and a storage unit 43.

The communication control unit 41 includes an embedded computer having a CPU and a memory. By executing the program stored in the memory by the CPU, various functions of the relay device 40 are realized. Here, the program is recorded in advance in the memory of the computer, but may be provided through a telecommunication line such as the Internet, or may be recorded and provided in a recording medium such as a memory card.

The communication unit 42 performs wireless communication using radio waves as a medium via the antenna 421. The communication method of the communication unit 42 is preferably a communication method that does not require a license for a radio station, and may be the same communication method as the communication unit 15 of the power tool 10 and the communication unit 32 of the management device 30.

The storage unit 43 is composed of a device selected from ROM, RAM, EEPROM, and the like. The storage unit 43 stores identification information (address, etc.) assigned to the relay device 40, work result information received from the power tool 10, and the like.

(2.4) Operation Description The operation of the power tool 10 of the present embodiment is controlled below.

When the user turns on the power switch of the power tool 10, the control unit 14 starts operation, and the control unit 14 drives the drive unit based on the input signal from the operation unit 12 and the detection result by the detection unit 13. Set the operating state of 11.

In the present embodiment, there are three operating states of the drive unit 11, a working state, a standby state, and a stopped state. The working state is a state in which the drive unit 11 drives the tool (socket 24). The standby state is a state in which the operation of the drive unit 11 is not prohibited, and the drive unit 11 is not in operation. The stopped state is a state in which the operation of the drive unit 11 is prohibited while the power tool 10 is not being used.

As shown in Table 1, the control unit 14 sets the operating state of the driving unit 11 to the working state, the standby state, and the stopped state based on the input signal from the operation unit 12 and the detection result by the detection unit 13. Set to either. The control unit 14 controls the operating state of the driving unit 11 to the set operating state.

When the detection unit 13 detects that the control unit 14 is in the non-holding state, the control unit 14 controls the operating state of the drive unit 11 to the stopped state. In the stopped state, the control unit 14 stops the operation of the drive unit 11 regardless of the presence or absence of an input signal from the operation unit 12. The stopped state is a state in which the power tool 10 is not held by the user, for example, a state in which the power tool 10 is placed at a work site or a storage place, or a state in which the user hooks the power tool on a belt and holds it. Is.

When the control unit 14 is detected by the detection unit 13 as a holding state and there is an input signal from the operation unit 12, that is, when the operation unit 12 is operated by the user, the control unit 14 changes the operation state of the drive unit 11. Control to the operating state. In the operating state, the control unit 14 operates the drive unit 11 to operate the tool (socket 24) in the drive unit 11. The control unit 14 may operate the drive unit 11 according to the setting information (for example, the set value of the tightening torque) acquired from the management device 30 in the operating state. The operating state is a state in which the user is operating the operation unit 12 with the power tool 10, and the user is in a state in which the tightening work is performed using the power tool 10.

The control unit 14 is in the operating state of the drive unit 11 if there is no input signal from the operation unit 12, that is, if the operation unit 12 is not operated by the user when the detection unit 13 detects the holding state. To the standby state. The control unit 14 stops the drive unit 11 in the standby state. The standby state is a state in which the user has the power tool 10 but does not operate the operation unit 12, and the user is moving with the power tool 10 or the user is electric. It is in a state of preparing to work with the tool 10.

As described above, the control unit 14 of the present embodiment controls the operation state of the drive unit 11 to the operation state set based on the input signal from the operation unit 12 and the detection result by the detection unit 13. .. Therefore, in order to set the operating state of the drive unit 11, the user needs to perform another operation other than the operation of grasping the grip unit 21 by hand and the operation of pulling the trigger switch 121 to rotate the tool. There is no need to reduce the time and effort required for operation. Conventional power tools are provided with a switch to prohibit the rotation of the electric motor, and by operating this switch, the electric motor (tool) does not rotate when an object hits the trigger switch during storage. I have to. In this case, the user needs to operate a switch for prohibiting the rotation of the electric motor, and if the operation is forgotten, the electric motor may rotate without permission due to an object hitting the trigger switch. In the power tool 10 of the present embodiment, when the operating state of the drive unit 11 is set to the stopped state by the control unit 14, the control unit 14 of the drive unit 11 regardless of the presence or absence of an input signal from the operation unit 12. Since the operation is stopped, the possibility that the drive unit 11 operates unintentionally by the user can be reduced.

Further, when the control unit 14 controls the operating state of the drive unit 11 to the working state, the drive unit 11 drives the tool to perform the bolt tightening work. The control unit 14 stores the measurement result taken from the acceleration sensor 172 at a predetermined sampling cycle and the measurement result of the torque measurement unit 171 as work result information when the drive unit 11 is operating in the working state. It may be stored in 18. Further, the control unit 14 stores the measurement result of the force sensor 131 taken in from the detection unit 13 at a predetermined sampling cycle in the storage unit 18 as work result information when the drive unit 11 is operating in the working state. You may.

Further, when the operation state of the drive unit 11 is controlled to the standby state or the stop state, the control unit 14 receives the setting information from the management device 30 and transmits the work result information to the management device 30. At least one of the operations may be performed by the communication unit 15.

Here, an operation in which the control unit 14 causes the communication unit 15 to perform a transmission operation of transmitting work result information to the management device 30 in a standby state or a stop state will be described.

The control unit 14 reads the work result information and the identification information that have not been transmitted to the management device 30 from the storage unit 18 in the standby state or the stop state, and includes the work result information and the identification information read from the storage unit 18. The transmission data is transmitted from the communication unit 15 to the relay device 40.

The communication unit 42 of the relay device 40 receives the transmission data transmitted from the power tool 10. When the communication unit 42 receives the transmission data from the power tool 10, the communication control unit 41 stores the work result information included in the transmission data in the storage unit 43. Here, the transmission data from the power tool 10 includes the identification information of the power tool 10 of the transmission source, and the communication control unit 41 stores the work result information included in the transmission data for each power tool 10. Store in 43.

For example, at a preset transmission time, the communication control unit 41 of the relay device 40 reads data of untransmitted work result information from the storage unit 43, and the read work result information and the electric power of the transmission source of the work result information. The transmission data including the identification information of the tool 10 is created. Then, the communication control unit 41 causes the communication unit 42 to transmit the created transmission data to the management device 30. The relay device 40 may cause the management device 30 to transmit the received work result information data each time the transmission data including the work result information is received from the power tool 10.

When the communication unit 32 of the management device 30 receives the transmission data from the relay device 40, the signal processing unit 31 stores the work result information included in the transmission data in the storage unit 35. Here, since the transmission data from the relay device 40 includes the identification information of the electric tool 10 that is the transmission source of the work result information, the signal processing unit 31 uses the work result information included in the transmission data as the electric tool. Every 10 is stored in the storage unit 35. As described above, since the work result information is stored in the storage unit 35 of the management device 30 for each power tool 10, the management device 30 uses the power tool 10 from the work result information for each power tool 10. It is possible to determine whether or not the work performed was appropriate.

Next, an operation in which the control unit 14 causes the communication unit 15 to perform a reception operation for receiving setting information from the management device 30 in a standby state or a stop state will be described.

When the operation state of the drive unit 11 is controlled to either a standby state or a stop state, the control unit 14 transmits transmission data including a request signal requesting setting information and identification information from the communication unit 15 to the relay device 40. To send to.

The transmission data transmitted from the power tool 10 is received by the relay device 40. When the communication unit 42 of the relay device 40 receives the transmission data from the power tool 10, the communication control unit 41 creates transmission data including the received request signal and the identification information, and uses this transmission data as the communication unit 42. To the management device 30.

When the communication unit 32 of the management device 30 receives the transmission data from the relay device 40, the signal processing unit 31 electricizes the request source based on the request signal and the identification information included in the transmission data from the relay device 40. Create setting information according to the future work contents by the tool 10. This setting information includes, for example, information on a set value of a bolt tightening torque.

The signal processing unit 31 of the management device 30 creates transmission data including setting information and identification information of the requesting power tool 10, and causes the communication unit 32 to transmit the transmission data to the relay device 40.

When the communication unit 42 of the relay device 40 receives the transmission data from the management device 30, the communication control unit 41 causes the communication unit 42 to transmit the setting information included in the transmission data to the requesting power tool 10. When the communication unit 15 of the requesting power tool 10 receives the transmission data from the relay device 40, the control unit 14 stores the setting information included in the transmission data in the storage unit 18.

The control unit 14 performs the subsequent tightening work according to the setting information stored in the storage unit 18. That is, when the control unit 14 controls the operating state of the drive unit 11 to the working state according to the input signal from the operation unit 12 and the detection result of the detection unit 13, the control unit 14 follows the setting information stored in the storage unit 18. It controls the operation of the drive unit 11. As a result, the power tool 10 can control the operation of the drive unit 11 in the working state according to the setting information received from the management device 30 in the standby state or the stopped state.

By the way, when the drive unit 11 is driving the electric motor, it is possible that the communication unit 15 and the outside (for example, the relay device 40, etc.) cannot normally perform wireless communication due to electromagnetic noise generated from the electric motor or the like. There is sex. In the present embodiment, the control unit 14 of the power tool 10 causes the communication unit 15 to perform a work result information transmission operation and a setting information reception operation in a standby state or a stop state in which the drive unit 11 is stopped. Therefore, there is an advantage that the possibility of a communication error is reduced.

As described above, in the electric tool management system 1 of the present embodiment, since the electric tool 10 transmits the work result information to the management device 30, the signal processing unit 31 of the management device 30 has acquired from the electric tool 10. The work content can be analyzed using the work result information.

The work result information includes information on the measurement results of the torque measuring unit 171 and the acceleration sensor 172, and information on the measurement results of the force sensor 131.

For example, the signal processing unit 31 of the management device 30 compares the work result information acquired from the power tool 10 with the setting information transmitted to the power tool 10, so that the work performed using the power tool 10 is appropriate. Determine if it was a good task. The signal processing unit 31 of the management device 30 compares the tightening torque information (actual value) included in the work result information with the set value of the tightening torque, so that the actual value of the tightening torque is within the allowable range of the set value. Judge whether or not.

Further, the signal processing unit 31 of the management device 30 can determine whether or not the user can master the power tool 10 based on the information of the measurement result of the acceleration sensor 172 acquired from the power tool 10. If the output of the power tool 10 is excessive compared to the muscle strength of the user, when the screw tightening work is performed using the power tool 10, the user loses the power of the power tool 10 and the tool body 20 rotates. There is a possibility that it will end up. Therefore, when the signal processing unit 31 of the management device 30 detects the rotation of the tool body 20 based on the measurement result of the acceleration sensor 172 while the drive unit 11 is operating, the power tool 10 conforms to the user's ability. It is determined that this is not the case, and the determination result is output to the display unit 33. The signal processing unit 31 of the management device 30 determines whether or not the power tool 10 is suitable for the user's ability, and the result is determined from the communication unit 32 via the relay device 40 to the mobile terminal 50 (FIG. 3). See). The mobile terminal 50 is a mobile terminal (smartphone or the like) used by the user of the power tool 10 or the supervisor who supervises the work, and the user or the supervisor of the power tool 10 uses the mobile terminal 50 to make a judgment result. Can be grasped.

Further, the signal processing unit 31 of the management device 30 may monitor the vibration and the load force applied to the user of the electric tool 10 based on the information of the measurement result of the force sensor 131 acquired from the electric tool 10. The signal processing unit 31 of the management device 30 can measure the vibration and load force applied to the user of the electric tool 10 based on the information of the measurement result of the force sensor 131, and the measurement result is used for improving occupational safety and health. can.

Further, the control unit 14 of the power tool 10 may be configured to switch to the alert state and issue an alarm when the received signal strength of the radio wave received from the relay device 40 becomes smaller than the preset reference level. .. The communication unit 42 of the relay device 40 periodically transmits a radio wave (beacon), and the radio wave transmitted from the relay device 40 is received by the communication unit 15 of the power tool 10. The communication unit 15 of the power tool 10 has a function of measuring the received signal strength of the received radio wave. If the received signal strength of the radio wave received from the relay device 40 is equal to or higher than the first reference level, the control unit 14 of the power tool 10 indicates that the power tool 10 is in the first area A1 (the circle with the reference numeral A1 in FIG. 3). It is judged to exist in the inner area). When the received signal strength of the radio wave received from the relay device 40 becomes less than the first reference level, the control unit 14 of the power tool 10 determines that the power tool 10 has moved to the outside of the first area A1. Further, when the strength of the received signal of the radio wave received from the relay device 40 becomes less than the second reference level, the control unit 14 of the power tool 10 causes the power tool 10 to move to the second area A2 (circle with reference numeral A2 in FIG. 3). It is judged that it has moved to the outside of the area inside). The first area A1 is an area where the strength of the received signal of the radio wave is equal to or higher than the first reference level, and is an area where the power tool 10 is normally used. The second area A2 is an area where the received signal strength of the radio wave is equal to or higher than the second reference level. For example, when the power tool 101 is present at the position P1 in FIG. 3, the received signal strength of the radio wave received by the communication unit 15 of the power tool 101 is equal to or higher than the first reference level, and the control unit 14 of the power tool 101 is electrically operated. It is determined that the tool 101 exists in the first area A1. Further, when the power tool 101 is present at the position P2 in FIG. 3, the received signal strength of the radio wave received by the communication unit 15 of the power tool 101 becomes smaller than the second reference level, and the control unit 14 of the power tool 101 controls the power tool 101. It is determined that the power tool 101 exists outside the second area A2.

When the received signal strength of the radio wave received from the relay device 40 becomes less than the first reference level, the control unit 14 of the power tool 10 determines that it has moved to the outside of the first area A1 and operates in a warning state. In the alert state, the control unit 14 of the power tool 10 blinks the display unit 16, sounds the built-in buzzer (not shown), vibrates the built-in vibration motor (not shown), and the like. Notifies that the user has moved to the outside of the first area A1.

When the received signal strength of the radio wave received from the relay device 40 becomes less than the second reference level, the control unit 14 of the power tool 10 determines that it has moved to the outside of the second area, and operates in the theft notification state. In the theft notification state, the control unit 14 of the power tool 10 blinks the display unit 16, sounds the buzzer (not shown) at a louder volume, vibrates the vibration motor more loudly, and so on. Notifies that it has moved to the outside of area A2.

In this way, the control unit 14 of the power tool 10 moves the power tool 10 to the outside of the preset usage area (first area A1) based on the received signal strength of the radio wave received by the communication unit 15. If it is determined, it operates in a vigilant state. The control unit 14 of the power tool 10 causes the notification unit (display unit 16, buzzer, etc.) to perform a notification operation in the alert state, and notifies that the power tool has been taken out of the area of use. 10 is less likely to be stolen.

The control unit 14 of the power tool 10 may grasp the current position by a GPS (Global Positioning System) receiver (not shown) built in the power tool 10. When the control unit 14 of the power tool 10 determines that the current position grasped by the GPS receiver is outside the first area A1, it operates in a warning state, and the current position grasped by the GPS receiver is the second area A2. If it is determined that it is on the outside, it may operate in the theft notification state.

Further, when the control unit 14 of the power tool 10 determines that the power tool 10 has moved to the outside of the first area A1, the communication unit 15 transmits a notification signal notifying the management device 30 that the power tool 10 has moved to the outside of the first area A1. You may let me. When the management device 30 receives the notification signal from the power tool 10 via the relay device 40, the management device 30 causes the display unit 33 to display that the power tool 10 has moved to the outside of the first area A1. When the management device 30 receives the notification signal from the power tool 10 via the relay device 40, the management device 30 may cause the mobile terminal 50 to transmit information indicating that the power tool 10 has moved to the outside of the first area A1. In this case, the management device 30 can output a warning sound or a warning message from the speakers (not shown) installed in the first area A1 and the second area A2, so that the power tool 10 is less likely to be stolen.

Further, when the management device 30 cannot communicate with the power tool 10 after receiving the notification signal from the power tool 10 via the relay device 40, the management device 30 determines that the power tool 10 has been stolen, and determines that the power tool 10 has been stolen. The theft may be displayed on the display unit 33 or notified to the mobile terminal 50.

(3) Modification Example The power tool 10 and the power tool management system 1 according to the modification of the first embodiment are listed below. It should be noted that each configuration of the modification described below can be applied in combination with each configuration described in the above embodiment as appropriate.

The power tool 10 of the present embodiment is, for example, an electric impact wrench, but the power tool 10 is not limited to the electric impact wrench. The power tool 10 may be an electric impact driver, an electric drill driver that is not a type that gives a striking force, or an electric torque wrench. In the present embodiment, the socket 24 for rotating the bolt is attached to the output shaft of the power tool 10, but a tool (tip tool) according to the work content is attached to the output shaft of the power tool 10. In addition to the socket 24, the tip tool includes a plus bit and a minus bit used for screw tightening work, a drill and a hole saw used for drilling work, and the like.

In the present embodiment, since the user can operate the power tool 10 with one hand, the tool body 20 is provided with only one grip portion 21, but in the case of a power tool operated with both hands, the tool body 20 is provided. A plurality of grip portions 21 are provided. In this case, a plurality of force sensors 131 may be provided on the plurality of grip portions 21. If the detection results of the plurality of force sensors 131 are all less than the threshold value, the detection unit 13 detects that the force sensor 131 is in the non-holding state, and the detection result of at least one of the plurality of force sensors 131 is equal to or more than the threshold value. If so, it is detected that it is in the holding state. Further, if the detection results of the plurality of force sensors 131 are equal to or higher than the threshold value, the control unit 14 can determine that the work state is in which the power tool 10 is used, and the detection result of only one force sensor 131 is equal to or higher than the threshold value. For example, it can be determined that the power tool 10 is being conveyed.

The force sensor 131 of the power tool 10 is a pressure sensor formed in a sheet shape, but may be composed of a strain sensor or the like as long as it can detect the force applied to the grip portion 21.

The power tool management system 1 of the present embodiment includes a relay device 40 that relays communication between the power tool 10 and the management device 30, but if the management device 30 and the power tool 10 can directly communicate with each other, the relay device 40 It does not have to be. That is, the relay device 40 is not an essential configuration of the power tool management system 1, and can be omitted as appropriate.

(Embodiment 2)
The power tool 10A according to the second embodiment will be described with reference to FIG.

As shown in FIG. 4, the power tool 10A of the second embodiment includes a voice recognition synthesis unit 25, a speaker 251 and a microphone 252 in addition to the configuration of the power tool 10 of the first embodiment. Since the configuration is the same as that of the power tool 10 of the first embodiment except for the voice recognition synthesis unit 25, the speaker 251, and the microphone 252, the same reference numerals are given to the common components, and the description thereof will be omitted. ..

The voice recognition synthesis unit 25 includes a dedicated IC (Integrated Circuit) having a voice synthesis function and a voice recognition function. The voice recognition synthesis unit 25 synthesizes voice data and outputs it from the speaker 251. The voice input to the microphone 252 is converted into an electric signal by the microphone 252. The voice recognition synthesis unit 25 creates an acoustic model based on the electric signal input from the microphone 252, and performs a process of recognizing the content of the voice input to the microphone 252.

When the operating state of the driving unit 11 is changed based on the input signal from the operating unit 12 and the detection result by the detecting unit 13, the control unit 14 of the power tool 10A is preset at the timing when the operating state is changed. A voice message is created and output from the speaker 251. As a result, the control unit 14 of the power tool 10A can output a voice message according to the operating state at the timing when the operating state of the driving unit 11 is changed.

For example, when the user grabs the grip portion 21 of the power tool 10A and the control unit 14 changes the operating state of the driving unit 11 from the stopped state to the standby state, the voice recognition synthesis unit 25 is made to create a voice message. , Is output from the speaker 251. When the operating state of the driving unit 11 is changed from the stopped state to the standby state, the control unit 14 causes the voice recognition synthesis unit 25 to create a greeting to the user and a voice message conveying the work content, and the speaker 251 creates a voice message. You can output it. For example, after the greeting "Let's do our best today" from the speaker 251, a voice message telling the work contents such as "M8, 30N" should be output, and it will be done to the user of the power tool 10A from now on. You can inform the work contents.

Further, when the user releases the finger from the operation unit 12 after operating the operation unit 12 to perform the tightening work, the control unit 14 of the power tool 10A changes the operating state of the driving unit 11 from the operating state to the standby state. change. In this case, the control unit 14 of the power tool 10A may cause the voice recognition synthesis unit 25 to create a voice message for conveying the work result, and output the voice message from the speaker 251. The control unit 14 of the power tool 10A determines whether the work is good or bad based on the work result information measured by the measurement unit 17 and the setting information of the work content, and voice-recognizes and synthesizes a voice message to convey the work result. It may be created by the unit 25 and output from the speaker 251. For example, it suffices if the speaker 251 outputs voice messages such as "very good" and "M8, 30N, good", and the power tool 10A can be informed of the quality of the work. The control unit 14 may evaluate the quality of the work in, for example, five stages, and have the voice recognition synthesis unit 25 create a voice message for conveying the evaluation result, and the user of the power tool 10A may be made to work. You can tell the quality more concretely.

Further, when the user speaks to the microphone 252 after grasping the grip portion 21 of the power tool 10A, the words spoken by the user are recognized by the voice recognition synthesis unit 25 and output to the control unit 14. For example, when the user speaks to the microphone 252 of the power tool 10A, "What is the next task?", The voice recognition synthesis unit 25 recognizes the words spoken by the user and outputs them to the control unit 14. A response message to a user's question is registered in the control unit 14 in advance. In response to the question "what is the next work", the control unit 14 reads the setting information of the next work from the storage unit 18 and causes the voice recognition synthesis unit 25 to create a voice message to convey the work content. It is output from the speaker 251.

In this way, a plurality of response messages corresponding to the words spoken by the operator are registered in the control unit 14 of the power tool 10A, and are configured so that a simple conversation can be performed between the power tool 10A and the user. Has been done.

The configuration described in the second embodiment is not an essential configuration for the power tool and can be omitted as appropriate. The configuration described in the second embodiment is applied in combination with the configuration (including a modification) described in the first embodiment as appropriate.

As described above, the power tools 10 and 10A of the first aspect include a drive unit 11, an operation unit 12, a detection unit 13, and a control unit 14. The drive unit 11 drives a tool (socket 24, etc.). The operation unit 12 receives an operation for operating the drive unit 11. The detection unit 13 detects whether the tool body 20 is in a holding state held by the user or the tool body 20 is in a non-holding state not held by the user. The control unit 14 controls the operation state of the drive unit 11 to an operation state set based on the input signal from the operation unit 12 and the detection result by the detection unit 13.

According to the first aspect, when the user operates the operation unit 12 by holding the tool body 20 in order to perform the work using the power tools 10 and 10A, the control unit 14 causes the drive unit 11 to operate. The operating state can be controlled to the operating state set based on the input signal from the operation unit 12 and the detection result by the detection unit 13. Therefore, it is not necessary to perform any operation other than the operation of the user holding the tool body 20 and the operation of the operation unit 12 for the user to operate the drive unit 11, and the labor of the operation can be reduced. can.

In the power tool of the second aspect, in the first aspect, the control unit 14 sets the operating state of the drive unit 11 to the working state based on the input signal from the operation unit 12 and the detection result by the detection unit 13. It may be configured to control either a standby state or a stopped state. The working state is a state in which the drive unit 11 drives the tool. The standby state is a state in which the drive unit 11 is stopped in the holding state. The stopped state is a state in which the drive unit 11 is stopped in the non-holding state.

According to the second aspect, the operating state of the drive unit 11 can be controlled to any one of a working state, a standby state, and a stopped state without imposing an operation burden on the user.

In the power tool of the third aspect, in the second aspect, the acquisition unit (measurement unit 17) for acquiring the work result information regarding the work result by the tool and the communication unit 15 for communicating with the management device 30 are provided. , You may prepare further. The control unit 14 may be configured to cause the communication unit 15 to perform at least one of the reception operation and the transmission operation when the operation state of the drive unit 11 is controlled to the standby state or the stop state. The reception operation is an operation of receiving setting information for setting the operating conditions of the drive unit 11 from the management device 30. The transmission operation is an operation of transmitting the work result information acquired by the acquisition unit to the management device 30.

According to the third aspect, when the control unit 14 controls the operation state of the drive unit 11 to the standby state or the stop state, the communication unit 15 performs the reception operation and the transmission operation, so that the noise generated by the drive unit 11 is generated. There is an advantage that communication can be performed in a small number of states and communication errors are unlikely to occur.

In the power tool of the fourth aspect, in any one of the first to third aspects, the tool body 20 may be provided with a grip portion 21 which is a portion held by the user. The detection unit 13 may have a force sensor 131 provided on the grip unit 21 to measure the force applied to the grip unit 21. The detection unit 13 may be configured to detect the holding state based on the measurement result of the force sensor 131.

According to the fourth aspect, the force sensor 131 can detect whether it is in the holding state or the non-holding state by measuring the magnitude of the force applied to the grip portion 21.

In the power tool of the fifth aspect, in the fourth aspect, the tool body 20 may be provided with a plurality of grip portions 21. The detection unit 13 may have a plurality of force sensors 131 provided on each of the plurality of grip units 21. The detection unit 13 may be configured to detect the holding state based on the measurement results of the plurality of force sensors 131.

According to the fifth aspect, the detection unit 13 can detect the state in which the tool body 20 is held in more detail based on the measurement results of the plurality of force sensors 131.

The power tool management system 1 of the sixth aspect includes the power tools 10, 10A of any one of the first to fifth aspects, and a management device 30 for managing the work contents by the power tools 10, 10A.

According to the sixth aspect, it is possible to provide the power tool management system 1 provided with the power tools 10 and 10A capable of reducing the labor of operation.

1 Power tool management system 10,10A, 101,102,103 Power tool 11 Drive unit 12 Operation unit 13 Detection unit 14 Control unit 15 Communication unit 17 Measurement unit (acquisition unit)
20 Tool body 21 Grip part 24 Socket (tool)
30 Management device 131 Force sensor 171 Torque measurement unit (acquisition unit)
172 Accelerometer (acquisition unit)

Claims (1)

The drive unit that drives the tool and
An operation unit that accepts operations for operating the drive unit,
A control unit that controls the operating state of the drive unit based on an input signal from the operation unit, and a control unit.
The grip part that is provided on the tool body and is the part that the user has,
A force sensor for measuring a force applied to the grip portion for monitoring the vibration or load force applied to the user is provided.
Electric tool.

Images